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High-entropy electrolytes for practical lithium metal batteries

Author

Listed:
  • Sang Cheol Kim

    (Stanford University)

  • Jingyang Wang

    (Stanford University)

  • Rong Xu

    (Stanford University)

  • Pu Zhang

    (Stanford University)

  • Yuelang Chen

    (Stanford University)

  • Zhuojun Huang

    (Stanford University)

  • Yufei Yang

    (Stanford University)

  • Zhiao Yu

    (Stanford University)

  • Solomon T. Oyakhire

    (Stanford University)

  • Wenbo Zhang

    (Stanford University)

  • Louisa C. Greenburg

    (Stanford University)

  • Mun Sek Kim

    (Stanford University)

  • David T. Boyle

    (Stanford University)

  • Philaphon Sayavong

    (Stanford University)

  • Yusheng Ye

    (Stanford University)

  • Jian Qin

    (Stanford University)

  • Zhenan Bao

    (Stanford University)

  • Yi Cui

    (Stanford University
    Stanford University
    SLAC National Accelerator Laboratory)

Abstract

Electrolyte engineering is crucial for improving battery performance, particularly for lithium metal batteries. Recent advances in electrolytes have greatly improved cyclability by enhancing electrochemical stability at the electrode interfaces, but concurrently achieving high ionic conductivity has remained challenging. Here we report an electrolyte design strategy for enhanced lithium metal batteries by increasing the molecular diversity in electrolytes, which essentially leads to high-entropy electrolytes. We find that, in weakly solvating electrolytes, the entropy effect reduces ion clustering while preserving the characteristic anion-rich solvation structures, which is characterized by synchrotron-based X-ray scattering and molecular dynamics simulations. Electrolytes with smaller-sized clusters exhibit a twofold improvement in ionic conductivity compared with conventional weakly solvating electrolytes, enabling stable cycling at high current densities up to 2C (6.2 mA cm−2) in anode-free LiNi0.6Mn0.2Co0.2 (NMC622)||Cu pouch cells. The efficacy of the design strategy is verified by performance improvements in three disparate weakly solvating electrolyte systems.

Suggested Citation

  • Sang Cheol Kim & Jingyang Wang & Rong Xu & Pu Zhang & Yuelang Chen & Zhuojun Huang & Yufei Yang & Zhiao Yu & Solomon T. Oyakhire & Wenbo Zhang & Louisa C. Greenburg & Mun Sek Kim & David T. Boyle & Ph, 2023. "High-entropy electrolytes for practical lithium metal batteries," Nature Energy, Nature, vol. 8(8), pages 814-826, August.
  • Handle: RePEc:nat:natene:v:8:y:2023:i:8:d:10.1038_s41560-023-01280-1
    DOI: 10.1038/s41560-023-01280-1
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    Cited by:

    1. Jiawei Chen & Daoming Zhang & Lei Zhu & Mingzhu Liu & Tianle Zheng & Jie Xu & Jun Li & Fei Wang & Yonggang Wang & Xiaoli Dong & Yongyao Xia, 2024. "Hybridizing carbonate and ether at molecular scales for high-energy and high-safety lithium metal batteries," Nature Communications, Nature, vol. 15(1), pages 1-11, December.
    2. Chutao Wang & Zongqiang Sun & Yaqing Liu & Lin Liu & Xiaoting Yin & Qing Hou & Jingmin Fan & Jiawei Yan & Ruming Yuan & Mingsen Zheng & Quanfeng Dong, 2024. "A weakly coordinating-intervention strategy for modulating Na+ solvation sheathes and constructing robust interphase in sodium-metal batteries," Nature Communications, Nature, vol. 15(1), pages 1-14, December.
    3. Yanhua Zhang & Rui Qiao & Qiaona Nie & Peiyu Zhao & Yong Li & Yunfei Hong & Shengjie Chen & Chao Li & Baoyu Sun & Hao Fan & Junkai Deng & Jingying Xie & Feng Liu & Jiangxuan Song, 2024. "Synergetic regulation of SEI mechanics and crystallographic orientation for stable lithium metal pouch cells," Nature Communications, Nature, vol. 15(1), pages 1-12, December.

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